Fluid-assisted medical device

ABSTRACT

The invention provides a medical device that includes a housing, a tubular member extending from the distal end of the housing, a first arm extending from the distal end of the tubular member, the first arm including a first electrode, a second arm extending from the distal end of the tubular member, the second arm including a second electrode and being disposed coaxially with the first arm, at least one solution infusion opening on each electrode, and a solution delivery channel for delivery of a conductive solution to the solution infusion openings. According to the invention, at least one of the first arm or the second arm is translationally moveable, and at least one of the first arm or the second arm is adapted to be coupled to a source of radiofrequency energy. The invention also provides a corresponding method for treating blood vessels or other tissues of the body.

This application is a continuation of U.S. application Ser. No. 11/316,798, filed Dec. 22, 2005, now pending, which is a continuation of U.S. application Ser. No. 10/354,643, filed Jan. 29, 2003, now pending, which is a continuation of U.S. application Ser. No. 09/668,403, filed Sep. 22, 2000, now U.S. Pat. No. 6,558,385. The entire disclosure of each of these patent applications is herein incorporated by reference to the extent it is consistent.

FIELD OF THE INVENTION

This invention relates generally to the field of devices for use in surgery upon tissues of the body. More particularly, the invention relates to an electrosurgical device and methods of treatment of body tissues.

BACKGROUND OF THE INVENTION

Electrosurgical devices use electrical energy, most commonly radiofrequency (RF) energy, to cut tissue and/or cauterize blood vessels. During use, a voltage gradient is created at the tip of the device, thereby inducing current flow and related heat generation in the tissue. With sufficiently high levels of electrical energy, the heat generated is sufficient to cut the tissue and, advantageously, to cauterize severed blood vessels.

Current electrosurgical devices can cause the temperature of tissue being treated to rise significantly higher than 100° C., resulting in tissue desiccation, tissue sticking to the electrodes, tissue perforation, char formation and smoke generation. Peak tissue temperatures as a result of RF treatment of target tissue can be as high as 350° C., and such high temperatures may be transmitted to adjacent tissue via thermal diffusion. Undesirable results of such transmission to adjacent tissue include unintended thermal damage to the tissue.

One limitation of current electrosurgical devices arises from size constraints and dimensions. It is difficult to reach or gain access to some tissue and vessels due to anatomy and size constraints. Electrosurgical devices often have movable hinged scissors-like jaws at their tip that must open widely to be placed around the target tissue to be treated. Hinged jaws reduce visibility of the tip and often limit grasping capability of vessels due to force constraints. Further, devices currently used also often have long rigid shafts that cannot bend to maneuver around anatomical “tight” spots.

Laparoscopic or minimally-invasive surgery often involves multiple instrument passes through a trocar to achieve the desired tissue effect. Separate instruments are often required for coagulation and for cutting. Separate instruments may also be required to achieve surface hemostasis, such as when there is bleeding from the surface of an organ such as the liver. Multiple instrument passes are undesirable because they (1) waste valuable operating room time, (2) sometimes make it difficult to precisely relocate the target treatment site, (3) increase the risk of infection, and (4) increase the cost by increasing the number of different surgical instruments that are needed to complete the surgical procedure.

Accordingly, there is a need for a surgical device that reduces undesirable effects such as tissue desiccation and resulting tissue damage, char formation, smoke generation, and risk of infection, while at the same time providing improved accessibility to tissues and efficiency.

SUMMARY OF THE INVENTION

The invention provides an improved electrosurgical device for coagulating and cutting tissues of the body, utilizing the simultaneous infusion of a conductive solution and application of RF energy. This is accomplished with a device that includes a first electrode positioned on a first arm, and a second electrode positioned on a second arm, wherein at least one of the first arm or the second arm is translationally movable, and at least one of the first electrode or the second electrode is adapted to be coupled to a source of radiofrequency energy. The first arm and the second arm are coaxially arranged. In a preferred embodiment, the device comprises a housing having a proximal and a distal end; a tubular member having a proximal and a distal end, the tubular member extending from the distal end of the housing; a first, translationally movable arm extending from the distal end of the tubular member, the first arm including a first electrode; a second arm extending from the distal end of the tubular member, the second arm including a second electrode and being disposed coaxially with the first arm; at least one solution infusion opening on each electrode; and a solution delivery channel for delivery of a conductive solution to the solution infusion openings, wherein at least one of the first electrode or the second electrode is adapted to be coupled to a source of RF energy.

In a preferred embodiment, the first arm and second arm include at least one groove that surrounds the at least one solution infusion opening. Preferably, the groove(s) include spaced exit slots to allow conductive solution to exit the groove during use (e.g., when pressure is applied to tissues). The grooved arm serves to isolate the metal electrode from direct contact with bodily tissues being treated. Additionally, the grooved configuration provides constant spacing between the electrode and tissue to be treated. Further, the groove assists in preventing tissue pressure against the solution infusion openings during squeezing of the arms of the device, which could inhibit or reduce the flow of electrically conductive fluid locally.

Preferably, the device further comprises a translationally movable cutting mechanism to transect tissue after it has been coagulated. The device can also be used to achieve surface hemostasis with no special adjustments or removal of the instrument from the patient.

In a preferred embodiment, the device further includes a locking mechanism, to selectively lock one or both of the arms of the device in a desired position.

The invention also provides a corresponding method for treating tissues of the body, including, for example, blood vessels. The invention is useful for ligating and dividing a dorsal vein or other blood vessels that are located in deep cavities of the body, as well as for procedures involving polyp removal and laparoscopic tubal ligations.

The invention provides a combination of advantages. For example, the device provides conductive solution, such as saline, at the electrode-tissue interface to limit the peak tissue temperature, preferably to 100° C. or less. The provision of saline at the interface prevents tissue desiccation and the various effects of desiccation, such as tissue sticking to the electrodes, perforation of adjacent organs or tissue structures, char formation on electrodes and adjacent tissue, and smoke formation. The saline at the interface preferably maintains peak tissue temperature at or below 100° C. by (1) providing coupling of the electrode to the tissue with a wetted contact area that is much larger than that of a dry electrode, thus reducing current density and local RF heating near the electrode-tissue interface, (2) providing a convective cooling effect, such that the flowing liquid saline is heated by the warmer surface of RF-heated tissue, and (3) providing an evaporative cooling effect, such that excess RF power that cannot be conducted or convected away from the target tissue will be used to boil some fraction of the saline provided to the treatment surface.

The invention also provides an instrument that has a lower profile than standard coagulating forceps with hinged jaws. In a preferred embodiment, the device includes a tubular member that has an articulating or bending feature to enable the distal end effector region of the device, including first and second arms, to pass around anatomical features. According to the invention, the device is capable of being made with an outside diameter that is 25 mm or less.

Preferably, the device is capable of being made with an outside diameter that is 15 mm or less, more preferably 5 mm or less. As used herein, the outside diameter is the maximum size that the tubular member or first and second arms achieve as a result of device operation.

The invention further provides a multi-purpose instrument that can be used to provide both coagulation and cutting of tissue without having to be removed from the patient's body. In one embodiment, the instrument is fabricated so that it is capable of sealing and cutting a vessel, as well as causing surface hemostasis on tissue such as bleeding liver.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a side view of a device according to one embodiment of the invention.

FIG. 2 is an open side view of the device of FIG. 1.

FIG. 3 is an enlarged side cross-sectional view of the distal end of the device of FIG. 1.

FIG. 4 is a perspective view of one embodiment of first and second electrodes of the invention.

FIG. 5 is a perspective view showing the operation of the device of FIG. 4 at a surgical site.

FIG. 6 is side view of the distal end of one embodiment of the invention.

FIG. 7 is a side view of the embodiment shown in FIG. 6, demonstrating the operation of the device at a surgical site.

FIG. 8 is a side view of the embodiment shown in FIG. 6, demonstrating the operation of the device including a cutting mechanism at a surgical site.

FIG. 9 is a top view of the embodiment shown in FIG. 6, wherein the first electrode and cutting mechanism are retracted.

FIG. 10 is a cross-sectional view taken along line 10-10 of FIG. 9.

FIG. 11 is a cross-sectional view taken along line 11-11 of FIG. 9.

FIG. 12 is an end view of an embodiment of a grooved arm of the invention.

FIG. 13 is a side view of the embodiment shown in FIG. 12, showing an embodiment of the device with a plurality of exit slots from a groove.

FIG. 14 is a cross-sectional view taken along line 14-14 of FIG. 13.

FIG. 15 is a top view of the distal end of the device, demonstrating operation of the device of FIG. 6.

FIG. 16 is a top view of the distal end of the device, demonstrating operation of the device of FIG. 6.

FIG. 17 is a cross-sectional view taken along line 17-17 of FIG. 16.

FIG. 18 is a cross-sectional view taken along line 18-18 of FIG. 16.

FIG. 19 is an enlarged cross-sectional view taken along line 17-17 of FIG. 16, demonstrating saline flow and current paths during RF application.

FIG. 20 is a side cross-sectional view of the one embodiment of the device, including porous metal electrodes.

FIG. 21 is a side cross-sectional view of an alternative embodiment of the device, including porous polymer electrodes.

FIGS. 22 a and 22 b are schematic side views of two embodiments of the electrical connections to the arms and/or the cutting mechanism of the device.

FIGS. 23 a-23 e show various shapes for the cutting mechanism of the invention.

FIG. 24 is a perspective view of an alternative embodiment of the electrode of the invention.

FIG. 25 is a perspective view of the embodiment of FIG. 24, showing treatment of a blood vessel.

FIGS. 26 a-26 b show the coagulation and cutting pattern for a small vessel according to one embodiment of the invention.

FIGS. 27 a-27 d show the coagulation and cutting pattern for a larger vessel according to one embodiment of the invention.

FIG. 28 shows one embodiment of the device involving coagulative surface “painting” with no tissue between the electrodes.

FIG. 29 is a side view of one embodiment of the invention, including an articulating tubular member.

FIG. 30 is a top view of the embodiment of FIG. 29.

FIG. 31 is a top view of an alternative embodiment of the device, including a second electrode as a ball tip.

FIG. 32 is a top view of the device shown in FIG. 31, demonstrating operation of the device.

FIG. 33 is a side cross-sectional view of the embodiment shown in FIG. 31

FIG. 34 is a side cross-sectional view of the embodiment shown in FIG. 32.

FIG. 35 is a top view of one embodiment of the invention.

FIG. 36 is a cross-sectional view along line 36-36 of FIG. 35.

FIG. 37 is a cross-sectional view along line 37-37 of FIG. 35.

FIG. 38 is an end view of the embodiment shown in FIG. 35.

FIG. 39 is a side cross-sectional view of an alternative embodiment of the device.

DETAILED DESCRIPTION

The invention provides a medical device that comprises a first electrode and a second electrode, wherein the electrodes are disposed coaxially to each other, and at least one of the electrodes is translationally movable. Preferably, the first electrode is provided on a first arm, and the second electrode is provided on a second arm of the device. According to the invention, the device comprises at least one translationally movable arm that can be selectively movable to a fixed position. Preferably, the device includes a locking mechanism, to allow the operator to move at least one arm of the device to a desired position and lock the arm in that position. Each electrode is provided with conductive solution. In a preferred embodiment, the electrodes include at least one groove to assist in delivery of the conductive solution to tissue.

In a preferred embodiment, the invention provides a medical device comprising a housing having a proximal and a distal end; a tubular member having a proximal and a distal end, the tubular member extending from the distal end of the housing; a first, translationally movable arm extending from the distal end of the tubular member, the first arm including a first electrode; a second arm extending from the distal end of the tubular member, the second arm including a second electrode and being disposed coaxially with the first arm; at least one solution infusion opening on each electrode; and a solution delivery channel for delivery of solution to the solution infusion openings. The device is configured such at least one of the first and second arms is adapted to be coupled to a source of radiofrequency energy. The invention can be used to treat tissues of the body, including blood vessels and surfaces of organs, such as the liver. Although the invention will be described herein in relation to these mentioned applications, it is understood that the device has other applications as well, and these are considered within the scope of the invention.

In the present description, elements in common between the embodiments of the figures are numbered identically, and such elements need not be separately discussed.

One preferred embodiment of the device is illustrated in FIG. 1. As shown in FIG. 1, housing 1 of the device includes an actuation member 2 and a trigger 3. Extending from the distal end of the housing is tubular member 6. Extending from the distal end of the tubular member 6 are the first arm containing first electrode 8 and the second arm including second electrode 9, end portion 25, and platform portion 26. The first arm, second arm, and cutting mechanism 7 together comprise the end effector region E of the device. In a preferred embodiment, the cutting mechanism 7 is translationally movable, preferably independently from movement of the first and second arms. At the proximal end of the housing is located a solution supply tube 4, which delivers saline or other electrically conductive solution under pressure from a solution supply 10 to solution infusion openings located on the electrodes 8 and 9. Also at the proximal end of the housing are two conductors 5 that conduct RF from an RF generator 11 to the electrodes 8 and 9 of the device. Each component of the device will now be described in detail.

Referring to FIG. 1, a housing 1 includes two actuators, an actuation member 2 that controls the translational movement of at least one of the arms, and a trigger 3 that controls the translational movement of the cutting mechanism 7. As illustrated, in a typical operation, the actuation member 2 can be actuated by the thumb of the operator, whereas the trigger 3 can be actuated by the index finger of the operator. However, the precise configuration of the actuation member 2 and trigger 3 is not critical to the invention, and other configurations can be used to achieve translational movement of the cutting mechanism and arms, respectively. Preferably, the first and second arms are independently movable from the cutting mechanism, such that the operator can selectively move one or more arms of the device, the cutting mechanism, or all of these components, as desired.

Attached to the distal portion of the housing is the tubular member 6. The tubular member 6 includes a lumen through which the actuation rods for the arms and cutting mechanism, the solution delivery channel, and the conductors pass. Although the dimensions of the tubular member 6 can be adapted for a desired purpose, the tubular member is preferably long (approximately 10 to approximately 50 cm, preferably approximately 20 cm to approximately 40 cm, more preferably approximately 25 cm to approximately 35 cm), with a diameter of about 2 mm to about 20 mm, preferably about 3 mm to about 10 mm. In one embodiment, the tubular member 6 is circular in outer shape and rigid, so as to pass easily through a trocar. Alternatively, the tubular member 6 is malleable. In yet another embodiment, the tubular member includes a deflectable tip that can be controlled by the surgeon during use, e.g., by using a wire connected to the tip that can be pulled to deflect the tip to one side.

At the most distal end of the tubular member 6 is located the end effector region E, comprising a collection of components that function together to cause the desired tissue effects to occur. This end effector region E of components consists of the cutting mechanism 7, the first arm with first electrode 8 and the second arm with second electrode 9, and is shown circled in FIG. 1.

At the proximal portion of the housing is located the fluid supply tube 4, which contains saline or other electrically conductive solution such that the fluid flows into the solution supply channel in the housing from a source 10 such as an intravenous bag of solution hung from an intravenous (IV) pole, a pressurized elastomeric canister, a syringe pump, an intravenous volumetric infusion pump, or a peristaltic pump. Other configurations of supply sources can be provided, to achieve the purposes described herein. Also at the proximal portion of the housing are two wires 5, which are connected to a radiofrequency generator 11 such that electrical power is supplied to the device. It is contemplated that the device can include one cable that connects the radiofrequency generator to the electrodes of the device. The electrical connection can be made to be switched with a foot switch, a hand switch or both.

In one embodiment, the solution supply source 10 comprises a pressurized canister that can be adapted to be received within the housing 1, or it can be provided externally. When the solution supply source is received within the housing 1, the portion of the fluid supply tube that extends from the proximal portion of the housing can preferably be eliminated. In a further embodiment, the solution supply source can be attached to the exterior of the housing. The provision of the solution supply source as an internal component of the device, or as a component attachable to the exterior of the housing, thus preferably eliminates the “tethering” effect of a solution supply tube that runs from the proximal portion of the housing to an external supply source that is separate from the housing.

In yet another embodiment, the housing 1 may contain an electrical switch to turn the solution supply source on or off.

In still another embodiment, the housing 1 can contain a mechanical valve or flow control device, such that moving a linear or rotating piece from one position to another increases or decreases the flow resistance, and hence the flow rate of solution. Such a valve can be continuously adjustable or can be arranged to provide a series of pre-set levels of flow resistance such that the flow rate can be adjusted in fixed increments.

Additionally, the solution could be provided at a much higher “flush” rate that can be selected using an electrical switch located on the housing 1, or via a foot switch. Similarly, an additional tube can be provided to the distal region of the device to provide suction to rapidly remove accumulated blood, saline or other fluid in the operative site. In one embodiment, suction at the tip is activated by occluding a small circular opening located on the housing 1 (e.g., by virtue of the operator using a finger to cover the hole when suction is desired). With the suction always turned on, occluding the hole enables the suction “intake” to move from the hole in the housing to the tip of the device.

FIG. 2 shows an “open” side view of the device. “Open” in this context means that this is not precisely a cross-sectional view with cut-away faces of internal components. FIG. 2 illustrates one embodiment of how the actuators connect to components in the end effector of the device. Actuation member 2 is slidably disposed within a slot formed in the housing 1. Within the housing 1, the actuation member 2 is connected to a proximal end of an arm actuation rod 12, which runs from the actuation member within the housing and through the entire length of the tubular member 6.

In the embodiment shown in FIG. 2, at its distal end, the arm actuation rod 12 is connected to the first arm, which includes first electrode 8. Arm actuation rod 12 is connected to the first arm through crimping or other conventional connectors, or may be integrally formed with the first arm. Movement of the actuation member 2 in the distal direction causes corresponding distal movement of the arm actuation rod 12 within tubular member 6, which results in corresponding distal movement of the first arm; conversely, movement of the actuation member 2 in the proximal direction causes corresponding proximal movement of the arm actuation rod 12, which results in corresponding proximal movement of the first arm. As the first arm moves distally, it decreases the distance between the first arm and second arm, thereby compressing a blood vessel or other piece of tissue between the first arm and the second arm. In the embodiment shown, the second arm 9 is stationary.

With continuing reference to FIG. 2, cutting mechanism 7 is connected at is proximal end to cutting actuation rod 15 through crimping or other conventional connectors. The distal end of cutting actuation rod 15 is attached to cutting mechanism 7 by, for example, crimping, soldering, pinning, and the like, and the proximal end of the cutting actuation rod 15 is located within housing 1. At or near its proximal end, cutting actuation rod 15 includes gear rack 14. Trigger 3 is provided with pinion 13 that includes gear teeth which engage the gear rack 14. When trigger 3 is moved in the direction of arrow A, pinion 13 rotates and engages gear rack 14. The meshing of the gear teeth of pinion 13 and the gear rack 14 causes the cutting actuation rod 15 to move distally within tubular member 6. This, in turn, causes distal movement of cutting actuation rod 15, extending the cutting mechanism 7 distally from the device.

At its proximal end, gear rack 14 is operably connected to spring 16. Spring 16 is secured within housing 1 to anchor it in a desired location. Spring 16 serves to bias (e.g., push or force) cutting mechanism 7 proximally, thus returning the cutting mechanism 7 to a retracted position when trigger 3 is released, as shown in FIG. 2. Preferably, gear rack 14 further includes ridge 17, which serves as a limiter of distal cutting mechanism movement when it comes into contact with stop 18. Stop 18 is located within housing 1 at a position that is distal relative to gear rack 14. Thus, when trigger 3 is moved in the direction of arrow A, thereby rotating pinion 13 which engages gear rack 14, the gear rack 14, along with cutting actuation rod 15, moves in the distal direction. Distal movement of the gear rack 14 and cutting actuation rod 15 is stopped by contact of ridge 17 with stop 18. The purpose of the limiting mechanism described is to limit distal movement of the cutting mechanism 7, such that it does not come into contact with the second arm or second electrode, or extend distally beyond the second arm, thereby cutting tissue that may not be treated with the electrodes and thereby coagulated. It is to be understood that modifications to the limiter mechanism described herein can be made without departing from the invention. It is apparent that the gear ratio, not shown to scale, is described to close the electrodes with less than a 180° travel.

Tubular member 6 extends from the distal end of the housing 1. Tubular member 6 is preferably made from a non-conductive polymer material such as polycarbonate, LCP (liquid crystal polymer) or other extrudable material that has moderate to high temperature resistance. Alternatively, tubular member 6 is fabricated from a metal, such as stainless steel or the like, and coated with a polymer material mentioned above. Tubular member 6 includes a lumen, though which the cutting actuation rod 15, arm actuation rod 12, solution delivery channel 4 and conductors 5 pass. The outside diameter of tubular member 6 is preferably of a size for passing through a cannula and the length is sufficient to reach an internal blood vessel to be cauterized or tissue to be treated when the tubular member is slidably inserted through the cannula and into the body of a patient, as discussed above.

Tubular member 6 may be integrally formed with the housing 1, or it may be secured to housing 1 in a suitable manner, such as with adhesives, or using such techniques as press-fit, heat-staking or ultrasonic welding.

The device includes end effector region, as shown labeled in the figures as E, which will now be described in more detail. The device of the invention provides a first, translationally movable arm and a second arm that is disposed coaxially with the first arm. As used herein, “coaxially” means the first arm and second arm are configured in a side-by-side arrangement, so that the arms extend in a parallel manner from the distal end of the tubular member 6. As discussed herein, the first arm of the device includes first electrode 8, and the second arm includes a second electrode 9. Thus, as the first arm moves in the distal direction, it approaches the second arm of the device. As each arm includes its respective electrode, movement of the first arm, with its first electrode, towards the second arm, with its second electrode, allows the user to grasp tissue to be treated with the arms and apply RF energy to treat the tissue as desired.

FIG. 3 illustrates an enlarged view of the end effector region E of one embodiment of the invention. The end effector region of the device includes the first arm including first electrode 8, the second arm including second electrode 9, and an optional cutting mechanism 7 (described in more detail below).

According to a preferred embodiment of the invention, each arm of the device is provided with its own solution delivery channel and conductor. As shown in FIG. 3, a solution delivery channel 4 is located within the tubular member 6. The solution delivery channel 4 extends from a solution source 10 at its proximal end, to the end effector region of the device at its distal end. In one embodiment, the device includes a separate solution delivery channel for each arm of the device. Alternatively, as shown in FIG. 3, the device includes a single solution delivery channel 4 that splits within the tube 6 toward the distal end of the tube. The “split” solution delivery channel thus forks to form first tube 20 that is in fluid communication with the first arm, and second tube 21 that is in fluid communication with the second arm. As shown in FIG. 3, first tube 20 is somewhat coiled and has slack in it so that when the first arm moves translationally, the first tube 20 can accommodate the motion without stretching or kinking. The precise configuration of solution delivery channel 4 is not critical, and it is understood that modifications can be made to the embodiment shown to supply conductive solution to the first arm and second arm of the device.

In addition to including a solution delivery channel, each arm of the device preferably includes a conductor for conducting RF energy from a source to the electrodes. As shown in FIG. 3, conductor 22 (shown in broken lines) is in communication with the first arm and thus first electrode 8, and conductor 23 (shown in broken lines) is in communication with the second arm and second electrode 9. The conductors 22, 23 are connected to a source of energy 11, such as RF energy, at their proximal ends. At their distal ends, each conductor is connected with an electrode of an arm of the end effector region E. Conductors 22 and 23 can be provided in the form of wires or other suitable conductive materials. As shown in FIG. 3, conductor 22 can be configured to include some coiling and slack to accommodate the translational movement of the first arm. Each of the conductors, 22 and 23, are preferably insulated by a sheath of nonconductive polymer such as Teflon™, with the insulation in place everywhere along the wires except where the wires are connected to other components, where the insulation is stripped to enable good crimps, solders or other connectors. Other suitable insulation can be applied to the conductors and their connections.

FIG. 4 illustrates a perspective view of an embodiment of an end effector region of the device, including first and second electrodes, as well as a cutting mechanism. According to a preferred embodiment of the invention, the first and second electrodes, 8 and 9 respectively, are similar in shape and construction. Preferably, the first and second electrodes are substantially similar in size and dimensions. In one embodiment, for example, the first and second electrodes are provided in a 1:1 size ratio. In a preferred embodiment, each electrode has both an electrical connection and a solution connection, as discussed herein. One way to accomplish this is to use hollow stainless steel needle (e.g., hypodermic) tubing as the structural foundation of the electrode. As shown in FIG. 4, the electrode loop is similar to a rectangle which is bent up at one end. Preferably, when the electrode loop is bent, the angle formed by the bent loop is 90°. At the proximal end of the electrode, both the electrical and fluid connections are made. The electrical connection is made via a crimped or soldered connection of the inner braid of low resistance wire to the metal of the stainless steel tubing. The solution connection is such that the flow of electrically conductive fluid travels from a flexible polymer tubing (such as Tygon™ (PVC), Teflon™, and the like) to the stainless steel needle tubing. Once the electrical connection is made at the proximal end of the loop, electrical energy is conducted along the steel tubing without any significant loss in voltage or power. In the embodiment shown in FIG. 4, the conductive solution flows in both legs of the tubing, reaching the bent-up loop end where the solution leaves the metal tubing.

FIG. 5 is another perspective view showing two electrodes along with a blood vessel to be treated, and a cutting mechanism 7. As shown, the first electrode 8 and second electrode 9 can be used to grasp a blood vessel, shown in broken lines (or other tissue), during treatment. As described herein, the cutting mechanism can move translationally, whereas either or both of the first arm containing the first electrode, and the second arm containing the second electrode, can be stationary or translationally movable, as desired. According to the invention, at least one arm of the device is translationally movable.

FIG. 6 shows a side view of the end effector region of the device, with the first arm and the cutting mechanism 7 both fully retracted (i.e., located at a proximal, unextended position). The second arm is shown including a portion of exposed metal 9, representing the second electrode, an end portion of the arm 25, and an underside, or platform portion 26. As shown in FIG. 6, the second electrode 9 is insulated and the end portion 25 and platform portion 26 of the second arm are both fabricated of non-electrically conductive polymer. End portion 25 and platform portion 26 together form a right angle in this embodiment. The tissue, such as a blood vessel, to be compressed and treated with RF is shown in cross-section as 24. FIG. 7 shows the embodiment of FIG. 6, wherein the first arm has been advanced distally to compress the vessel 24. FIGS. 6 and 7 show the cutting mechanism 7 in a retracted, or fully proximal, position.

FIG. 8 shows another side view of the end effector region of the device after the cutting mechanism 7 has been fully advanced distally to cut through the compressed vessel 24. The broken lines show the position of the cutting mechanism within the device. As discussed herein, a stop located inside the housing preferably limits the distal motion of the cutting mechanism so that it does not come into contact with, or extend beyond, the distal edge of the second arm. Preferably, the first and second arms of the device include a guide slot to allow translational movement of the cutting mechanism, as discussed in more detail below.

FIG. 9 shows a top view of the end effector embodiment shown in FIG. 9. The cutting mechanism 7 and the first arm are shown in a retracted, or fully proximal, position. In one preferred embodiment, the second arm includes a platform portion 26 that comprises a generally flattened area located proximal the bent portion of the arm. The platform portion 26 is configured to accommodate tissue, such as a blood vessel, to be treated with the device. At the same time, the platform portion 26 is limited by the diameter of the tubular member 6, so that the second arm is capable of freely translating in the proximal and distal directions within the tubular member 6. The platform portion 26 can be used to hold a vessel or tissue to be treated in position prior to compression and RF treatment. Preferably, the platform portion 26 includes a guide slot 27, to allow translational movement of the cutting mechanism 7. When included in the device, guide slot 27 stabilizes and guides the cutting mechanism in a straight path when it is moved distally toward the second arm. In the embodiment shown in FIG. 9, the distal arm is preferably insulated to avoid treating tissue that is not positioned between the two arms of the device.

FIG. 10 shows a cross-sectional view along line 10-10 of FIG. 9. This view looks toward the proximal direction of the device, down the axis of the tubular member 6 toward the housing 1. In this embodiment, first arm is shown including a “U” shaped electrode 8 on its face. A series of small diameter holes that define solution infusion openings 28 are oriented around the surface of the first electrode 8. The entire surface of the first electrode 8 that is shown in this figure is exposed metal that may conduct electrical energy to tissue. Cutting mechanism 7 is seen with the sharp edge being the line down the middle of the centerline of the figure. The platform portion 26 that supports the second electrode is made of a non-conductive material such as a polymer or ceramic. Two legs of the second electrode loop tubing are buried in the platform portion 26, each shown with a thin wall 29 of stainless steel or other electrically conductive material, and a solution delivery tube 21 to convey saline or other electrically conductive fluid to the distal electrode. The solution delivery tube 21 comprises the distal portion of solution supply tube 4 of the device.

FIG. 11 shows a cross-sectional view along line 11-11 of FIG. 9. This view looks toward the distal end of the device, facing the exposed metal portion of the second, stationary electrode. In this embodiment, the shape of the distal electrode “bent-up” loop is “U” shaped, with a series of small diameter holes that define solution infusion openings 31 oriented around the surface of the electrode. Gap 32 indicates where the distal tip of the cutting mechanism (not shown) travels. The guide slot 27 that holds the lower part of the cutting mechanism is shown here in cross-section. In this embodiment, the platform portion 26 is shown as containing two tubing sections, each with a thin wall 29 and a solution delivery tube 21.

Solution infusion openings, in the form of a series of fine laser-drilled holes, each with a diameter of about 0.001 to about 0.010 inches, preferably about 0.005 to about 0.007 inches, allows the solution to exit the tubing. In an alternative embodiment, the solution infusion openings are formed by electrical discharge machining (EDM), chemical treatment, etching of the metal, or any suitable method for forming holes of the desired size in the tubing. Solution infusion openings are provided at sufficient intervals along the face of the electrode that will contact tissue to provide the desired effect. Preferably, the metal tubing is insulated everywhere except where it is desired that electrical energy be conducted to tissue. Preferably, at least one electrode is insulated.

The dimensions of the holes or openings and the spacing between holes, as well as the tubing inside diameter and tubing wall thickness are chosen so that the flow of saline is reasonably well distributed to all the openings. If the resistance to flow down the lumen of the tubing is small compared to the resistance to flow through an individual hole or opening, then all holes will provide sufficient flow for proper device operation. Generally, resistance to flow is inversely proportional to the fourth power of the diameter of the lumen or hole, so that doubling the size of the opening reduces resistance to flow to 1/16th of the initial value. Typically, the inside diameter of the tubing would range from 0.02 to 0.1 inches and wall thickness would range from 0.004 to 0.01 inches. However, it is understood that these measurements can be modified for a particular application as desired. In a preferred embodiment described in more detail below, solution infusion openings are included within a groove to achieve flow of conductive solution throughout the groove and across the surface of the electrode that is used to treat tissue as described herein.

Referring to FIG. 12, an alternative embodiment of the electrode is shown. In this embodiment, the needle tubing contains one or more portions where the insulation has been removed, forming an arm having an exposed portion of the electrode 8 that is recessed from the insulated portions. This results in a electrode having solution infusion openings contained in a groove 90 of the arm. Preferably, this grooved configuration further includes exit slots 92 to allow electrically conductive fluid to exit the groove and flow freely away from the distal end of the device. In this embodiment, the groove 90 serves to isolate the metal electrode from direct contact with bodily tissues being treated. Additionally, the groove 90 provides constant spacing between the electrode 8 and tissue to be treated. This in turn provides wet electrical coupling of the electrode to tissue, through the electrically conductive solution, at a constant distance. Further, the groove assists in preventing tissue from pressing against and occluding the solution infusion openings 28 during squeezing of the arms of the device against tissue. Such tissue pressure against solution infusion openings 28 could inhibit or reduce electrically conductive fluid locally. If saline is not provided at the electrode/tissue interface the proper coupling or conducting of RF electrical energy may not occur.

FIG. 13 shows a side view of multiple exit slots 92 emanating from a grooved electrode configuration as described above and shown in FIG. 12. In this embodiment, the exit slots 92 extend about groove 90 around the insulated metal electrode tubing to assure that solution can exit from the groove 90 without being blocked by compressed tissue. The recessed metal of the two electrodes 8 and 9 are shown as exposed by these side exit slots 92.

FIG. 14 shows how the face of the electrode from FIG. 13 appears when viewed along section 14-14 defined in FIG. 13. Exit slots 92 are provided in a spaced relation about groove 90 to provide outlet of the conductive solution, and the spacing of the exit slots 92 can be adjusted as desired.

In the embodiments shown in FIGS. 12-14, the exit slots 92 assist in preventing solution from being trapped in the groove 90. If there were a groove and no exit slots it would still be possible for tissue pressure to inhibit solution flow, since the groove would form a closed space between the electrode and the tissue. Solution pumped into such a closed space could exit by forcing open a gap between the tissue and the electrode insulation, for example, when the solution pressure in the space of the groove exceeded the pressure of the tissue pressing against the insulation. Though solution can ultimately leak out as tissue is coagulated and shrunk, the distribution of solution over the total electrode surface can be uneven and result in dry spots where RF energy is not conveyed to tissue as effectively. It is desirable to make the flow rate of solution independent of how hard the tissue is clamped between the two electrodes.

A preferred embodiment of the device includes a large number of relatively small exit slots, approximately 0.005 inches to approximately 0.020 inches wide and from approximately 0.005 inches to approximately 0.020 inches deep.

Alternatively, the groove is fabricated from electrically non-conductive porous polymer or ceramic, preferably polymer or ceramic composed of a material that is easily wetted by the electrically conductive solution. In this embodiment, the solution exits through the sides of the groove by passing through the porous polymer or ceramic material. Wettability is usually expressed in terms of the contact angle formed between a drop of liquid lying on a solid surface, with small angles representing better wettability than large angles. Using a porous material that is more wettable reduces the amount of pressure required to initially force solution through the fine pores. Teflon™ (polytetrafluoroethylene), for instance, is not as well wetted by saline as most ceramics, and thus would be less desirable as a material from which to form the groove.

Using a porous material for the groove creates a very large number of very small exit slots, and is one method of providing solution exits that provide for uniform flow distribution while also being simple to manufacture.

It should be understood that there can be more than a single groove on an electrode. If the electrode is more rectangular or square-shaped, it may be desirable to have a system of criss-crossing or cross-hatched grooves evenly distributed over the surface of the electrode. It will be appreciated that the precise pattern of such a plurality of grooves can be modified to any desired pattern, while maintaining a gap of conductive solution between metal electrode and tissue that is not subject to compression by tissue even when the electrodes are pressed firmly together.

In a preferred embodiment shown in FIGS. 12-14, the first electrode and second electrode each contain a groove 90, optionally further including exit slots 92. Preferably, the configuration of the groove 90 and exit slots 92 (when provided) are minor images on the first and second electrodes.

Slightly prior to and during RF application, a flow rate of conductive fluid, such as physiologic saline (“normal” saline, or 0.9% NaCl solution) or lactated Ringer's™, is provided so that a total flow rate of about 0.1 to 10 cc/min is flowing from laser-drilled holes located on the proximal and distal electrodes. Preferably, a total flow rate of about 0.5 to 2 cc/min is flowing from the laser-drilled holes. Other suitable conductive solutions include hypertonic saline and Ringer's™ solution.

In use, the first, translationally movable arm containing first electrode 8 is moved in a distal direction toward the second, stationary arm containing second electrode 9. FIG. 15 shows a top view of the end effector region of the device during use, showing the first electrode 8 and the second electrode 9 in position so that the blood vessel 24 is just in contact with each electrode. In this view, the blood vessel is captured between the arms of the device so that it is in contact with the electrodes of the device. The cutting mechanism 7 is shown as partially advanced from the tubular member.

FIG. 16 shows another top view of the end effector region after the first arm has been advanced as far in the distal direction as it can go, resulting in the compression of the blood vessel 24 against the second arm.

FIG. 17 shows a cross-sectional view along line 17-17 of FIG. 16. One lumen 33 of the first electrode 8 is shown, being very similar to one of the lumens 30 that supply the distal electrode 9. The small diameter holes (solution infusion openings 28 for the first electrode and 31 for the second electrode) are located so that saline or other conductive solution is supplied to the electrode-tissue interface. The insulation 25 that covers the distal end of the second arm is also shown in this section. FIG. 18 shows a cross-sectional view along line 18-18 of FIG. 16. As shown in FIGS. 17 and 18, lumens 33 and 30 are shown passing through the metal tubing of each of the first and second arms which, as indicated in the application above, may provide the structural foundation of electrode 8 and electrode 9.

FIG. 19 shows an enlarged cross-sectional view along line 17-17 of FIG. 16, with conductive solution flowing and RF electrical energy being applied. Conductive solution is indicated by the small arrows 34 flowing through one of two lumens and then through a number of solution infusion openings 28. In this view, the blood vessel 24 is separated from both the first electrode 8 and second electrode 9 by a gap 38 that is filled with conductive solution. The conductive solution is therefore a coupling agent that is most often between the metal of the electrodes and the tissue. The free surface or interface of the conductive solution and the air is indicated at 35. When a differential high frequency voltage is applied across the electrodes (8 and 9) current flows as shown by the thicker arrows 36. It will be appreciated that the gap 38 need not exist everywhere between the tissue and metal electrodes.

Some of the current may flow between the two electrodes without passing through the blood vessel 24, by only passing through a film of conductive solution. This situation may occur at the edges of the blood vessel or tissue being treated. The majority of the current will preferably pass through conductive solution and then through the tissue being treated. Under some circumstances the tissue can become hot enough to have some of the conductive solution boil, as shown by the small vapor bubbles 37 in the conductive solution film. It will be understood that when the device is used as a monopolar device, the solution need not be delivered to the electrode not in use.

The solution infusion openings of the electrodes supply conductive solution to the treatment site. In an alternative embodiment, these solution infusion openings can be provided in the form of porous material such as metal. In this embodiment, the electrodes do not include discrete laser drilled solution infusion openings; rather, the electrode surface itself is porous to allow infusion of the conductive solution to the treatment site. Porous sintered metal is available in many materials (such as, for example, 316L stainless steel, titanium, Ni-Chrome, and the like) and shapes (such as cylinders, discs, plugs, and the like) from companies such as Porvair, located in Henderson, N.C.

Porous metal components can be formed by a sintered metal powder process or by injection molding a two-part combination of metal and a material that can be burned off later to form pores that connect (open cell) to each other. Such methods are known in the art. In this embodiment, conductive fluid will flow out of the electrode everywhere the pores are open. Preferably, the exterior (i.e., the portions of the components that do not comprise the portion of the device involved in tissue treatment) of such porous metal electrode components can be covered with a material that fills the pores and prevents both the flow of saline and the passing of electrical energy.

FIG. 20 shows an enlarged cross-sectional view along line 17-17 of FIG. 16. In this embodiment, porous metal 44 comprises both first electrode 8 and second electrode 9. A portion of the outer surface of each electrode is insulated with a non-conductive polymer 45. In this embodiment, conductive solution flow 46 now travels through the porous metal 44 to wet the blood vessel 24. The surface of the conductive solution is shown as 35.

In yet another embodiment, a porous polymer is used in place of the porous metal. Although the polymer is non-conductive, the conductive solution provided will conduct the RF energy across the porous polymer wall and to the tissue to be treated. Suitable materials include high temperature open cell silicone foam and porous polycarbonates, among others. Porous ceramics would also fall into this category, since they could distribute flow, withstand high temperatures and be machinable or moldable for manufacturing purposes. Preferably, the material used transmits both fluid flow and electrical energy; thus, materials with properties midway between high-electrical conductivity metals and low electrical conductivity polymers are also contemplated, such as porous carbon-filled polymers.

Because the conductive solution, such as saline, is generally less electrically conductive than the previously described electrode metals (such as stainless steel), there are several steps that can optionally be taken to avoid dissipating an excess of electrical energy in the resistance of saline. Optionally, hypertonic saline is used instead of “normal” or physiologic saline. By adding more sodium chloride to the water it is possible to decrease the electrical resistivity of the solution by a factor of 3 to 5. Preferred hypertonic (i.e., saturated) saline includes 14.6% sodium chloride (NaCl) at 37° C. and has a resistivity of 5.9 ohm-cm. This is in contrast to “normal” saline, which is 0.90% NaCl, with resistivity of 50 ohm-cm at 37° C. (body temperature).

In yet another alternative embodiment, shown in FIG. 21, a wire electrode 48 is included in the first and second arms of the device. As shown in the figure, the wall of each of the hollow electrodes 8 and 9 comprises a porous polymer 47. Conductive solution 46 flows through the porous polymer wall. In previously described embodiments where the electrodes are fabricated from metal, the RF energy is conducted to the electrode-tissue interface by the metal in the wall of the electrode tubing. In the present embodiment, the metal is replaced by porous polymer, and a “replacement” electrical conductor can be used to provide RF energy to the inner wall of the porous polymer near the tissue to be treated. Electrical energy is supplied to the first electrode 8 from a wire electrode 48 that is preferably made of a metal such as platinum that resists corrosion. This wire is insulated by a sheath 49 of some non-conductive polymer such as Teflon™. The second electrode is supplied RF electrical energy by exposed electrode wire 50 which is insulated by sheath 51. Preferably, the outer surface of the porous polymer is insulated by another polymer coating 45, similar to the coating for porous metal electrodes, to keep conductive solution from flowing out of the first and second arms to locations where treatment is not desired. In this embodiment, the RF field lines 52 run from the exposed wire 48 through conductive solution, through the conductive solution in the porous polymer wall of the first electrode 8, through the solution gap and/or the blood vessel, to the corresponding elements of the device on the opposing side of the blood vessel to the second electrode's exposed wire 50. Alternatively, this porous polymer is fabricated from a solid polymer tube or hollow member that has mechanically or laser-drilled small diameter holes in it.

The frequency of the electrical energy is typically 500 kHz, and the power is typically in the range of about 10 to about 150, preferably in the range of about 30 to about 70 watts. A typical range of conductive solution flow rates is about 18-270 cc/hr. In a preferred embodiment, the total flow rate of conductive solution to both electrodes is approximately determined as 1.8 times the power in watts, with the result in cc/hr.

As discussed above, an RF source provides energy through the conductors, to the electrodes of the device. The RF source can be provided as a generator, as described. Alternatively, the source can be configured to be received within or attached to the housing of the device.

Optionally, the invention is provided with a cutting mechanism, indicated in the figures generally as 7. Preferably, the cutting mechanism 7 is independently movable from the first or second arm, or both. As described herein, the cutting mechanism serves to cut tissue preferably after application of RF energy, such that the tissue has been coagulated. Cutting tissue after coagulation reduces risk of bleeding from the tissues, especially with respect to highly vascularized tissue such as the liver, during treatment. However, it will be understood that the invention does not require tissue coagulation prior to cutting, for example in situations where bleeding is not a concern.

The cutting mechanism of the invention is preferably provided in the form of a sharp blade. However, it is apparent from the present description that the cutting mechanism need not be sharp, especially when the cutting mechanism is supplied with RF energy, as described below. In another embodiment, the cutting mechanism can be provided in the form of a wire. In yet another embodiment, the cutting mechanism is not itself sharp, but cuts tissue through the use of RF energy, as described herein.

Optionally, the device is configured to supply the cutting mechanism 7 with RF energy. Moreover, the device can be configured to allow the device to be switched between a bipolar mode in which RF energy is supplied to the first electrode, and a second bipolar mode in which RF energy is supplied to the cutting mechanism 7. FIGS. 22 a and 22 b illustrate this embodiment of the invention. FIG. 22 a shows the situation during treatment of blood vessel 24 (e.g., coagulation), with a switch 42 configured to provide RF energy to the first electrode 8. In this operating mode, one of the two electrical paths is connected to the first electrode 8, and the lower electrical connection is made to the second electrode 9. After the vessel has been coagulated and it is desired to cut the sealed vessel, FIG. 22 b shows switch 42 to operate the device in a second mode, wherein the electrical connection that previously supplied first electrode 8 in FIG. 22 a with RF energy is now connected to the cutting mechanism 7. In this mode, as cutting mechanism 7 moves into contact with the sealed vessel, the edge of the blade concentrates the RF field so that the RF energy aids in the cutting of the tissue. This feature is intended to provide improved cutting efficiency and minimize the effects of the blade becoming progressively more dull with use and less able to cut cleanly with minimal force.

The cutting mechanism of the invention can be provided in a variety of suitable configurations to achieve cutting of the tissue. FIGS. 23 a through 23 e illustrate a number of alternative shapes for the cutting mechanism, when provided in the form of a blade, with the arrow indicating the direction of cutting motion. As shown, the cutting mechanism can provide a right angle straight edge (FIG. 23 a), an angled edge with a recessed edge downward toward the platform portion 26 of the second arm (FIG. 23 b), an angled edge with a recessed edge upward (FIG. 23 c), a two-faceted edge (FIG. 23 d), or a rounded edge (FIG. 23 e). The sharp edge 43 is shown as a bolder line for all five of the variations shown. While it is intended that none of the additional variations of cutting mechanism shape would protrude beyond the distal electrode (e.g., for safety reasons) the different shapes are all intended to provide potentially improved cutting by recessing some part of the leading sharp edge. Other suitable shapes can be utilized to achieve the desired cutting according to the invention, and the shapes shown are illustrative only and should not be considered limiting.

As discussed herein, the cutting mechanism comprises an optional component of the device, to be used when the operator desires to cut a tissue or blood vessel during treatment. When the device is provided without a cutting mechanism, the first and second arms can be fabricated such that they do not include a slot to allow passage of the cutting mechanism through the arm and thereby through tissue. In this embodiment, the first and second arms are preferably provided in a “paddle-like” form, with varying amounts of roundness to the corners. This embodiment is depicted in FIGS. 24 and 25. FIG. 24 shows a schematic representation of a paddle-like electrode connected to a conductor for connection to a radiofrequency source. In this embodiment, the electrode surface 71 is provided with solution infusion openings 72 on its face. FIG. 25 shows a schematic representation of a paddle-like electrode configuration, showing the first and second electrodes, 8 and 9, positioned with a blood vessel 24 therebetween, and conductors 22 and 23. As shown, the electrodes are preferably substantially the same size.

Preferably, the electrodes of this embodiment are hollow, to allow the flow of conductive solution, and with thin walls to allow the passage of the solution through to tissue. The passage of conductive solution is through either (1) small holes in solid metal or solid polymer (e.g., as shown in FIG. 24) or (2) micro- or macroporosity in metal or polymer. If solid or porous polymer is used, then an internal “replacement” electrode wire can be used to provide RF close to the area where there is tissue (as previously described with respect to porous polymer electrodes). External portions of electrodes made with porous materials are preferably insulated electrically and made impervious to keep conductive solution from weeping out where not desired. One advantage of using paddle-like electrodes with otherwise larger surface areas is that the larger electrode areas can provide lower impedance to RF power and thereby faster treatment times.

Use

The device of the invention can be used to coagulate and cut body tissues, such as a blood vessel, in a variety of applications. Exemplary applications are described herein, without intending to be limited thereto. Further, it is understood that the description herein can be used to treat a number of body tissues, and the invention is not limited to treatment of tissues provided as examples.

FIG. 26 shows the coagulation and cutting pattern when the device is used on a blood vessel of diameter small enough to be coagulated and cut with a single pass. FIG. 26 a is oriented to view the blood vessel 24 and first electrode 8 when looking in a distal direction from the housing and down the tubular member 6. In this embodiment, the operator positions the device, the blood vessel is compressed, then RF is applied, resulting in the coagulation pattern shown in FIG. 26 b as coagulation zone 39. The coagulation zone 39 is shown as smaller than the total exposed metal electrode surface area, though it could be larger than the metal area. This is not a critical aspect of the invention, since the size of the coagulation zone is under the direct control of the surgeon who will typically use visual feedback (e.g., color) to determine when tissue has been adequately treated. The size of the coagulation zone is determined by a number of factors, including the length of time that the RF energy is applied, the power level of the RF, the conductive solution flow rate, the type and composition of the tissue, and the tissue compression force.

After cutting the blood vessel with the cutting mechanism 7, the result is shown in FIG. 26 b, as two separate pieces of the blood vessel 24. In the coagulation zones 39, the opposite walls of the blood vessel 24 are bonded together so that no blood flows from the edges of the cut.

FIG. 27 shows how the device can be used to coagulate and cut a larger blood vessel. As shown in the first of four figures, 18 a, the device is positioned and a U-shaped coagulation zone 39 is generated. The result of this treatment is shown as 27 b, the U-shaped coagulated zone 39, with a cut 40 in between. In order to coagulate and cut again to complete the vessel transection, FIG. 27 c shows how the device is positioned up into the cut 40 which has been spread apart by the platform portion 26 of the second arm. After compression and application of RF energy, followed by another cutting action, the transected vessel appears approximately as shown in FIG. 27 d, with the final coagulation zone shown as 39. The coagulation zone 39 shown for the two-step procedure is only schematic and not intended to be a precise rendering. A larger vessel could also be sealed by approaching the vessel from the opposite side for the second seal, instead of from the same side, as just described.

FIG. 28 shows an alternative way that the device can be used to treat tissue that is not grasped between the two electrodes, but rather is located in a noncoaptive manner adjacent to the distal end surface of the tips of the two electrode loops which, as shown in FIG. 28, along with other drawings, each comprise a spherical distal end surface. This type of operation is sometimes referred to as “coagulative surface painting.” With the first arm advanced distally, but not all the way forward (i.e., toward the second electrode), and both RF energy delivery and conductive solution flow turned on, the electrical field lines 36 are schematically shown, extending from the tip of first electrode 8 of the first arm, through tissue and conductive solution, to second electrode 9 of the second arm. The surface of the conductive solution 35 that has exited from the small holes extends downward in the direction of gravity to wet the surface 41 of the tissue. Vapor bubbles 37 may or may not be present in the conductive solution as a result of heat generated by the RF energy. The device need not be oriented as indicated in the figure for this mode of tissue treatment to occur; that is, the device can be used to treat tissue that is positioned above the device, since conductive solution will wet both the metal electrode and tissue surfaces, even in opposition to the force of gravity. The sides of the device could also be used to perform coagulative painting. In such an embodiment, the sides of the electrodes are provided with sufficient surface area to achieve the desired coagulative effect.

In a preferred embodiment, the device includes a locking mechanism. Once the optimum separation distance is achieved between the first and second electrodes, further movement of the first electrode is prevented by engaging an electrode locking mechanism that locks the position of the electrode. In one embodiment, this locking mechanism is located on the housing near the actuation member 2 (shown in FIGS. 1 and 2) that moves the first arm translationally. The locking mechanism is used to selectively lock and unlock the first arm in a desired position. In use, the physician determines the optimum distance between the arms, based upon visual feedback relating to how the end effector region of the device is interacting with tissue as the separation distance of the first and second arms is changed. For example, once the arm is locked in position it would be easier for the physician to “paint” the surface of a heavily bleeding organ, such as liver, without being concerned about the electrode moving and losing the desired effect. The locking mechanism also prevents the first electrode from inadvertently contacting the second electrode during use (e.g., during application of RF energy). Alternatively, the locking mechanism is provided in the activation member 2.

The locking mechanism is provided to lock one, or both of the arms. When the device includes a first arm that is translationally movable, and a second, stationary arm, the locking mechanism is provided to selectively lock the first arm in a desired position. In turn, when the device includes a second arm that is translationally movable, the locking mechanism is provided to selectively lock the second arm in a desired position. Alternatively, when both arms are translationally movable, the locking mechanism can selectively lock or unlock one or both of the movable arms.

Generally, as the first and second electrodes are moved closer together, a larger fraction of the conductive solution flow may boil, leading to a “hotter” tissue surface temperature. Conversely, as the electrodes are positioned further away from each other, a smaller fraction of the conductive solution will boil, leading to a lower surface temperature effect.

In another embodiment, the device is capable of treating areas of the body that are difficult to reach anatomical sites. In this embodiment, the device is provided with the ability to articulate or flex, to allow the end effector region of the device to access areas of the body requiring treatment that may be difficult to reach using minimally invasive or noninvasive techniques. As used herein, “articulate” means the tubular member is capable of moving about a joint or a jointed area as described herein. In one preferred embodiment, the tubular member 6 is provided with the ability to articulate, to allow the operator to maneuver the device within the patient's body to reach the treatment site. Alternatively, the tubular member 6 can be angled or flexible, to facilitate engaging a tissue from a selected approach position.

FIGS. 29 and 30 show one preferred embodiment of this device. As shown in FIG. 29, tubular member 6 includes an articulation zone 53 that is located a predetermined distance from the distal end of the device. In one embodiment shown in the figures, the area of the tubular member 54 that is located between articulation zone 53 and the first arm of the device is rigid, and the area of the tubular member 55 that is located on the proximal side of the articulation zone is also rigid. Within the articulation zone 53 is a rib construction of polymer ribs 56 separated by air gaps 57. Other suitable constructions of the articulation zone 53 are possible to achieve articulating movement of the tubular member. Alternatively, in an embodiment not shown, the areas of the tubular member 54 and 55 are flexible. Additionally, the device includes at least one articulation zone 53 and can include multiple articulation zones, as desired.

In one embodiment, rotatable knob 58 is located on the housing to control movement of the articulation zone 53, and thereby control articulation of the device. As rotatable knob 53 is rotated by small incremental amount, the articulation zone 53 bends a correspondingly small incremental amount. This bending or articulating is shown in FIG. 30. When the rotatable knob 58 is rotated through a series of detents, the articulation zone 53 goes through a series of small incremental bends, for example, of perhaps 5 degrees of arc per increment. The first offset view of the angled end effector 59 is at an angle of 30 degrees, and the second offset view of the end effector 60 is at an angle of 60 degrees. The enlarged top view of the articulation zone 53 shows the ribs 57 and gaps 56 during such articulating movement. When the articulation zone bends, the diameter of gaps 56 decreases on one side of the tubular member, and increases on the opposite side of the tubular member.

The invention has been described as a bipolar surgical device, whereby RF energy is supplied to the first and second electrodes, or to one of the electrodes and the cutting mechanism. Alternatively, the device can be provided as a monopolar surgical instrument. In this embodiment, only one of the first or second electrode is provided with RF energy and a flow of conductive solution. In one preferred embodiment, the first, translationally movable arm containing the first electrode is provided with conductive solution and RF as previously described. According to this embodiment, the second arm is provided as a structural component only and is not provided with solution or electrical energy. In an alternative preferred embodiment, the second electrode is provided with conductive solution and RF energy, as previously described. According to this embodiment, the first arm is provided as a structural component only and is not provided with conductive solution or electrical energy. When the device is used as a monopolar device, the second electrode is provided as a pad placed under the patient, as a ground, or a dispersive electrode.

The invention contemplates alternative configurations for the first and second arms, and the first and second electrodes. In one embodiment, the first arm of the device is provided in the form of a spring-loaded ball tip. As shown in FIG. 31, one configuration of the device includes a first arm in the form of a ball tip and a second arm configured in a paddle-like form. The tubular member 61, which corresponds to tubular member 6 of FIG. 1, comprises a non-conductive polymer and contains the outer sheath 62 of the ball shaft, also fabricated from a non-conductive polymer. According to this embodiment, the first arm of the device is provided in the form of outer sheath 62 of the ball shaft, and the first electrode is provided in the form of a ball 64. A spherical ball 64 is positioned within outer sheath 62 and is partially held in place by a rim 63 of the sheath 62. The second electrode is positioned within the second arm provided in the form of insulated spatula 65, that is attached to the tubular member 61 by a support member 66, also preferably insulated. In a preferred embodiment, the electrodes are configured such that the inner opposing surface area of each is substantially the same size, such that the surface area of the ball that contacts tissue is substantially the same as the surface area of the second electrode (e.g., spatula). Preferably, the electrode surface areas that contact and treat tissue are provided in a 1:1 ratio. Preferably, ball 64 is fabricated from a suitable metal, such as stainless steel and the like.

FIG. 32 shows a top view of the embodiment of FIG. 31 with the ball advanced distally to compress the vessel 24 against the second electrode.

FIG. 33 shows a cross-sectional view of the embodiment shown in FIG. 31. The tubular member 61 contains the outer insulating sheath 62 of the ball shaft, the rim 63 and the ball 64. The rim 63 is part of a tubular structure 67 that conveys both electrical energy and a flow of conductive solution, such as saline, to the tip of the ball. In a preferred embodiment, the rim and tubular structure 67 are fabricated of a suitable metal, such as stainless steel and the like. Conductive solution, such as saline, flows from the housing in the tube 67, through a number of holes 68, past spring 70 which pushes the ball 64 against the rim 63, and out to the outer surface of the ball through gouges 75. The saline flow clings to the surface of the ball 64 and the rim 63 through the action of surface tension. Saline flowing to the ball is shown as 69 as it passes through the holes in the tubular structure that holds the spring in place. Spring 70 biases the ball 64 in a distal direction, thereby urging the ball 64 against rim 63.

In one embodiment, the second electrode is comprised of a plate 71 with a plurality of holes 72 in it, that convey a flow of conductive solution 74 down a lumen 73. The distal end portion 65 of the second arm comprises insulation covering the second electrode. Preferably, the plate 71 is metal.

FIG. 34 shows a cross-sectional view of the embodiment shown in FIG. 32. In this figure, the ball shaft is advanced proximally to compress the blood vessel 24 against the second electrode.

FIG. 35 is a top view of another embodiment of the invention. FIG. 36 shows a view along line 36-36 of FIG. 35, looking proximally at the spherical surface of the ball 64. A radial series of small gouges 75 in the rim 63 allows conductive solution to flow freely around the rim of the ball even when the spring is pressing the ball firmly against the rim. Also shown are the tubular member 61, the outer sheath 62 of the ball shaft, the lumen 73 in the second arm that conveys conductive solution to the second electrode, and insulated conductor 76 that conveys electrical energy to the second electrode 71.

FIG. 37 shows a view along line 37-37 of FIG. 35, looking in a distal direction at the second arm of the device. According to this embodiment, the second arm includes second electrode 71 with holes 72, lumen 73, and conductor 76. The connection of conductor 76 to the distal electrode 71 is not shown, but can be accomplished with a crimp of a tab of the electrode 71 that would at least partially wrap around the conductor before crimping.

FIG. 38 is an end view of the distal end of the device, showing the blood vessel 24, the insulated covering 65 of the second arm, the tubular member 61 and the metal rim 63.

The ball embodiment of the invention provides a combination of advantages. For example, if the ball becomes clogged with char it can easily be unclogged by pressing the ball distally against the second arm. As the ball is pushed against any solid object, the spring 70 compresses and the ball moves proximally to a position behind the rim 63, thus breaking off any adherent char. This unclogging feature is not intended to be routinely used, since the presence of saline normally prevents the creation of any char. However, there may be circumstances when the physician may inadvertently misuse the device by excessively turning up the power or turning down the flow rate, which might result in boiling off all the flow off saline, drying out the “wetness” of the device and causing char formation as the tissue temperature rises significantly above 100° C.

Preferably, when the first electrode of the device is provided in the form of a ball, the second arm is shaped with a concave surface facing the convex shape of the first electrode. This “matching” of electrode shapes provides improved electrode-tissue contact and hence faster and more uniform tissue coagulation. Alternatively, the second electrode of the device is provided in the form of a ball (FIG. 39), in which embodiment, the first arm can be shaped with a concave surface.

The invention provides a combination of advantages over electrosurgical devices in the art. The device provides tissue coagulation and cutting without tissue desiccation, sticking, perforation, smoke formation, char formation, or thermal spread of high temperatures. Further, the invention provides electrodes of a variety of shapes and orientations that are supplied with a flow of saline in order to maintain the electrode-tissue interface continuously wetted during the application of RF energy. This “wet” electrode design will limit the peak tissue temperature to 100° C. or less and prevent tissue sticking, tissue perforation, smoke formation, char formation, and high temperature thermal spread. These advantages lead to faster, easier and safer surgical procedures.

Further, the device of the invention provides the ability to treat tissue and vessels in hard-to-reach places. One preferred configuration of the device as a tubular, angled coagulator with a movable first electrode and an optional movable cutting mechanism leads to the advantage of a low profile both during insertion and during actuation, compared to scissors-type devices. The articulating end effector region of the device also confers a significant advantage of being able to reach difficult anatomical sites. This ultimately leads to faster surgical procedures, reduced cost and increased safety. Moreover, the ability to access hard-to-reach areas of the body for treatment using the device may allow surgeons to perform noninvasive or at least minimally invasive procedures. This in turn avoids risks associated with open surgical procedures, such as risk of infection, longer healing time, and the like.

The invention thus provides a multi-purpose instrument that can be used to provide both vessel or tissue coagulation and cutting, plus surface coagulation for stopping surface bleeding without having to remove the device from the trocar.

The design of the device enables bipolar coagulation and cutting without having to remove the device from its location at the target tissue. The device can also optionally be used in the bipolar mode to perform surface coagulation or coagulative “painting” with the space between the bipolar electrodes empty of tissue. The flow of saline is effective in achieving good coupling of RF energy to tissue even when used in this painting mode.

Additionally, the invention provides a device that can be used as a monopolar or bipolar device, and is switchable between the two modes.

The invention has been described with reference to various specific and preferred embodiments and techniques. However, it will be apparent to one of ordinary skill in the art that many variations and modifications may be made while remaining within the spirit and scope of the invention.

All publications and patent applications in this specification are herein incorporated by reference, to the extent it is consistent, and to the same extent as if each individual publication or patent application was specifically and individually incorporated by reference. 

1. A medical device comprising: a. a housing having a proximal end and a distal end; b. a tubular member having a proximal and a distal end, the tubular member extending from the distal end of the housing; c. a first translationally moveable arm extending from the distal end of the tubular member, the first arm including a first electrode; d. a second arm extending from the distal end of the tubular member, the second arm including a second electrode and being disposed coaxially with the first arm; e. at least one solution infusion opening on each electrode; f. a solution delivery channel for delivery of a conductive solution to the solution infusion openings, wherein at least one of the first arm or the second arm is adapted to be coupled to a source of radiofrequency energy. 2-35. (canceled) 